Vertebral Support Device

ABSTRACT

A vertebral support device ( 1 ) is disclosed, which in various embodiments comprises at least two osseous anchoring implants ( 2 ), each designed to be anchored to a vertebra, and at least one linking element ( 3 ) fixed to the osseous anchoring implants ( 2 ) by fasteners ( 20 ) that maintain a fixed angle between the longitudinal axis (L) of the linking element ( 3 ) passing through rigid elements ( 34 ) of the linking element ( 3 ) and the insertion axis (DV) of the implants ( 2 ). The linking element ( 3 ) includes at least one elastic dampening element ( 31 ) that that allows the implant-bearing vertebrae some freedom of movement. The dampening element ( 31 ) accommodates the stresses imposed on the linking element ( 3 ) during movement of the vertebrae and tends to return the support device ( 1 ) to its normal configuration.

RELATED APPLICATIONS

This application claims priority under 35 U.S.C. §119 to French PatentApplication No. 06 11198, filed in FRANCE on Dec. 21, 2006.

TECHNICAL FIELD

This present invention concerns intervertebral devices and prosthesesthat can be implanted onto the spinal column, and more particularly avertebral support device.

BACKGROUND

It would be advantageous to have a vertebral support device thatsupports the vertebrae on which it is implanted, while still offering acertain freedom of movement of the vertebrae and, as a consequence,preventing the fusion of these vertebrae, unlike various knownosteosynthesis devices.

Various types of osteosynthesis devices are discussed, for example, inpatent applications WO02/080788 and WO95/10240 and in patents, U.S. Pat.No. 5,603,714, and U.S. Pat. No. 5,437,669. These devices include atleast two bone-anchoring implants, each designed to be anchored to avertebra and connected together by a linking element (an osteosynthesisbar), using fasteners such as clamps to securely attach thebone-anchoring implants and the linking element. By immobilizing thevertebrae on which it is implanted, this type of device is used toachieve intervertebral fusion, to reduce spondylolisthesis or to correctscolioses or other defects of the spinal column. Also, patentapplications WO03/049629, EP 0572790, WO 2005/020829, and WO 00/15125,and patent U.S. Pat. No. 5,501,684 discuss various types of vertebralanchoring implants facilitating, to varying degrees, the fitting ofelements of the osteosynthesis device, the reduction ofspondylolisthesis, or the correction of defects of the spinal column.However, these devices provide no freedom of movement of the vertebraeand lead to a fusion of the vertebrae on which they are implanted, whichhas the disadvantage for the patient of limiting movement and oftransferring the stresses normally experienced by these vertebrae ontothe adjacent vertebrae and onto the adjacent intervertebral discs.Patent applications WO02/080788, WO03/049629, and WO 2005/020829 areassigned to the assignee of the present application, and areincorporated by reference herein for all purposes.

Other references discuss vertebral support devices comprising osseousanchorage implants linked together by a flexible linking element. Forexample, patents U.S. Pat. No. 5,672,175, U.S. Pat. No. 4,743,260, andU.S. Pat. No. 7,083,622 discuss vertebral support devices havingimplants that are linked together by a flexible bar. These devices allowonly a lateral movement, thereby accommodating stresses occurringlaterally with respect to the axis of the spinal column but not in thedirection of flexion or extension of the spinal column. Patentapplications WO 91/16018 (corresponding to patent EP 0 381 588 B1), WO2004/089244 (corresponding to patent U.S. Pat. No. 6,966,910 B2) and WO03/037216 (corresponding to patent U.S. Pat. No. 6,783,527 B2) discussvertebral support devices in which the linking element between theimplants generally comprise an elastic ligament maintaining a permanenttension between the implants. This type of elastic ligament, used alone,tends to bring the implants together along with the vertebrae on whichthey are attached, and does not provide an adjustable orientation of thelinking element with respect to the implants or of the position of thearticulation. Patent applications WO 98/22033 (corresponding to patentU.S. Pat. No. 6,267,764 B1) and WO 2005/030031 discuss support devicesthat comprise an elastic ligament fixed to bars linked to the implants,which allows a measure of positioning of the articulation between theimplants, but these devices do not necessarily allow an adjustment ofthe orientation of the bars, and these devices do not provide a centralportion absorbing the stresses in compression occurring between theimplants. Patent EP 0 669 109 B1, for example, discusses a supportdevice comprising an elastic ligament surrounded by an elastic centralportion absorbing the stresses in compression between the implants, andpatent application WO 2005/092218 discusses a device comprising anelastic ligament inserted in rigid spacers fitting together and forminga string with the ligament. In these devices, however, the implants restdirectly on the central portion or the rigid spacers, which does notpermit adjustment of the orientation or the position of the articulationbetween the implants. Patent U.S. Pat. No. 5,540,688 (corresponding topatent EP 0 516 567 B1) discusses a device comprising an elasticligament surrounded by a central dampening portion and, in someembodiments, by additional surrounding elements. The position of theligament with respect to the implants cannot be adjusted, nor can thepoint of articulation.

SUMMARY

In this context, the present invention provides various embodimentshaving various features and combinations of features addressing some ofthe disadvantages of other designs. For example, a vertebral supportdevice is provided that can be used to maintain (or restore) thedistance (along the axis of the spinal column) between the vertebrae onwhich it is implanted (maintain or restore a height between thevertebrae), while preventing the arthrodesis (definitive immobilizationand intervertebral fusion) of some or all of such vertebrae. Variousembodiments of the support device provide flexible articulation thatallows some freedom of movement of these vertebrae, which can relievethe intervertebral disc by absorbing part of the stresses that candamage the disc. In some embodiments, correction of defects of thespinal column can be accomplished by maintaining a permanent tensionbetween the vertebrae, which limits separation of the vertebrae whileallowing adjustment of the position of articulation between the implantsand adjustment of the orientation of the support device with respect tothe spinal column.

Various embodiments of the present invention provide selected featureswith a vertebral support device (1) comprising at least two osseousanchoring implants (2), each designed to be anchored to a vertebra alongan insertion axis (DV) and at least one linking element (3) connectingthe osseous anchoring implants (2) and having a longitudinal axis (L).The linking element (3) comprises rigid elements (34) and a dampeningelement (31) having a central elastic portion (32) and a longitudinalelastic portion (33), with the rigid elements (34) articulated by thedampening element (31).

The articulation of the rigid elements (34) provides freedom of movementto the vertebrae on which the device (1) is attached. In variousembodiments, the dampening element (31) accommodates the stressesexperienced by the linking element (3) during these movements, and tendsto return the device (1) to its normal configuration. In variousembodiments, the central elastic portion (32) of the dampening element(31) cooperates with rigid element (34) to accommodate the compressionstresses occurring on the linking element (3), and the longitudinalelastic portion (33) accommodates the extension or flexion stressesoccurring on the linking element (3). For many applications of thevarious embodiments described in this disclosure, each implant (2) isanchored to the pedicles of a vertebra along an axis called adorso-ventral (DV) axis. Accordingly, the insertion axis along which animplant (2) is anchored to a vertebra will be referred to herein as a“dorso-ventral axis (DV),” which nomenclature, as discussed furtherbelow, is adopted solely for convenience of description. Thus, areference in this specification to a “dorso-ventral axis (DV)” shall bea reference to any axis of insertion for an insert, and shall not limitthe insertion axis to any particular place or any particularorientation. In addition, this specification uses the nomenclature“longitudinal axis” as a general and nonlimiting reference to adirection in which an elongated object is elongated, as more fullydiscussed below.

In selected embodiments, a fastener (20) fixes each rigid element (34)to an implant (2) so that after the fastener is tightened thelongitudinal axis (L) of the linking element (3) extending through therigid element (34) and the insertion axis (DV) of the implant (2)establish a fixed angle.

In selected embodiments, the longitudinal elastic portion (33) comprisesends, each fixed with respect to the implants (2) and/or to the rigidelements (34) by fasteners (330, 331).

In selected embodiments, the central portion (32) of the dampeningelement (31) is located substantially equally distant from each of theimplants (2) between which it is located, on the longitudinal axis (L)of the linking element (3).

In selected embodiments, the position of the central portion (32) of thedampening element (31) between the implants (2) is off-centre in thelongitudinal axis (L) of the linking element (3).

In selected embodiments, the dampening element (31) is composed of atleast one elastic material.

In selected embodiments, the dampening element (31) comprises at leastone elastic weave or braid of synthetic fibers, with the stitches ofthis weave or the plaits of this braid being tightened to varyingdegrees, to adjust the elastic properties of the dampening element (31)according to the desired elasticity.

In selected embodiments, the central portion (32) of the dampeningelement (31) has an outside diameter that is, to varying degrees, largerthan the outside diameter of the tubes (34) of the linking element (3).

In selected embodiments, the tension of the elastic longitudinal portion(33) can be adjusted with the fasteners (330, 331).

In selected embodiments, the elastic longitudinal portion (33) includes,at least close to at least one of its ends, at least one tension markthat can be used to identify at least one position at which thefasteners (330, 331) must block the longitudinal portion (33) in orderto achieve at least one given tension on the longitudinal portion (33).

In selected embodiments, the linking element (3) includes two hollowtubes (34) that each includes an internal conduit in which is mounted anelastic longitudinal portion (33) of the dampening element (31), saidelastic longitudinal portion (33) having a length that is substantiallygreater than the length of the linking element (3), with the two ends ofthe longitudinal portion (33), protruding from the hollow tubes (34),each being held fixed in relation to the tubes (34) using fasteners(330, 331) of the longitudinal portion (33).

In selected embodiments, the rigid elements are solid bars, each havingan end cooperating with the fasteners, such as clamps (20), of theimplants (2) and an end cooperating with the central portion (32), theelastic longitudinal portion (33) being parallel to these hollow tubesand having a length substantially greater than the length of the linkingelement (3).

In selected embodiments, the solid bars comprise a groove, channel, orchute allowing the insertion of the longitudinal portion (33), thefasteners, such as clamps (20), thus resting on the solid bars (34) andnot on the longitudinal portion (33).

In selected embodiments, the groove, channel, or chute extends, at thefixation extremity of the solid bars (34) cooperating with theclamps(20), by a hole allowing the insertion of the longitudinal portion(33), the groove being closed by a surface for supporting the fasteners,such as clamps (20).

In selected embodiments, the central portion (32) and the longitudinalportion (33) of the dampening element (31) form a unitary block, withthe junctions between the central portion (32) and the longitudinalportion (33) of the dampening element (31) forming recesses, eachaccepting one end of one of the rigid elements (34).

In selected embodiments, the central portion (32) and the longitudinalportion (33) of the dampening element (31) comprise a unitary weave orbraid of synthetic fibers, in which the size of the links of the weaveor of the plaits of the braid is substantially identical on the twoportions (32 and 33), which therefore have the same elastic properties.

In selected embodiments, the elastic properties of the central portion(32) and of the longitudinal portion (33) of the dampening element (31)are different, although they form a unitary block, due to a weave orbraid having different degrees of tightness in the two portions (32 and33).

In selected embodiments, the central portion (32) and the longitudinalportion (33) of the dampening element (31) are two separate elements,the central portion (32) being hollow and having an inside diameter thatis substantially identical to the outside diameter of the longitudinalportion (33).

In selected embodiments, the central portion (32) and the longitudinalportion (33) of the dampening element (31) each comprise a weave orbraid of synthetic fibers, with the size of the links of the weave or ofthe plaits of the braid being substantially identical on the twoportions (32 and 33), which therefore have the same elastic properties.

In selected embodiments, the elastic properties of the central portion(32) and of the longitudinal portion (33) of the dampening element (31)are different, due to a weave or braid having different degrees oftightness in the two portions (32 and 33).

In selected embodiments, the two weaves or braids of the central (32)and longitudinal (33) portions are stitched together.

In selected embodiments, the central portion (32) and the longitudinalportion (33) comprise different materials.

In selected embodiments, the inside diameter of the central portion (32)is substantially smaller than the inside diameter of the hollow tubes(34) of the linking element (3), the outside diameter of thelongitudinal portion (33), at the central portion (32), beingsubstantially identical to the inside diameter of the central portion(32) and, at the hollow tubes (34), being substantially identical to theinside diameter of the hollow tubes (34).

In selected embodiments, the inside diameter of the central portion (32)and the outside diameter of the longitudinal portion (33) aresubstantially identical to the inside diameter of the hollow tubes (34)of the linking element (3).

In selected embodiments, the central portion (32) includes, close to itscentre along the longitudinal axis (L), at least one slot (320) orcutout, located on at least one surface of the linking element (3) andfacilitating the bending of the latter during movement of the patient onwhich the device (1) is intended to be implanted.

In selected embodiments, the central portion (32), on either side of itscentre along the longitudinal axis (L), includes a chamfer (321) facingeach of the rigid elements (34) located on at least one surface of thelinking element (3) and facilitating the bending of the latter duringmovement of the patient on which the device (1) is intended to beimplanted.

In selected embodiments, the two rigid elements (34), at their end incontact with the central portion, include (32) a rounded externalprofile (341) that fits onto a recess (322) of complementary shapeinside the central portion (32), this complementarity of shapefacilitating the movement of the rigid elements (34) in relation to thecentral portion (32), during the bending of the linking element (3) inthe course of any movement of the patient on which the device (1) isintended to be implanted.

In selected embodiments, the hollow tubes (34) comprise, at their endsin contact with the central portion (32), on the one hand, a roundedexternal profile (341) that fits onto a recess (322) of complementaryshape inside the central portion (32), this complementarity of shapefacilitating the movement of the rigid elements (34) in relation to thecentral portion (32), during the bending of the linking element (3) inthe course of any movement of the patient on which the device (1) isintended to be implanted and, on the other hand, and a flared internalprofile (342), avoiding the compression and cutting of the longitudinalportion (33) inside the hollow tubes, during this bending.

In selected embodiments, the dampening element (31), on at least onepart of at least one of its surfaces, includes at least one bending stop(310, 311) opposing the bending of the linking element (3) duringmovement of the patient on which the device (1) is intended to beimplanted.

In selected embodiments, the bending stop (310, 311) is made from anelastic material to partially oppose the bending of the linking element(3).

In selected embodiments, the bending stop (310, 311) is made from arigid, inelastic material to totally oppose the bending of the linkingelement (3).

In selected embodiments, the rigid elements (34) includes at least oneflat (340), on at least one of their surfaces and at least at theposition of the clamps (20), said flat (340) cooperating with the clamps(20) so as to prevent the rotation of the rigid elements (34) aroundtheir longitudinal axis (L).

In selected embodiments, the osseous anchoring implants (2) includeanchors (21) that are used to attach the implants (2) to the vertebraeand each includes a conduit (22) intended to accept the linking element(3), with the fasteners such as clamps (20) including means fortightening the linking element (3) against an internal wall of theconduit (22), the cooperation between these means for tightening and theconduit (22) being used to hold the fixed angle between the longitudinalaxis (L) of the linking element (3) and the dorso-ventral axis of thevertebrae.

In selected embodiments, the fasteners (330, 331) of the longitudinalportion (33) include at least one removable lock, staple, ring, clip,pin, or stitch (330), clamping at least one end of the longitudinalportion (33).

In selected embodiments, the fasteners (330, 331) of the longitudinalportion (33) include at least one removable lock (300) that fits onto atleast one hole passing through the longitudinal portion (33), along anaxis that is substantially perpendicular to the longitudinal axis (L),where this hole constitutes a tension mark that is used to determine thetension of the longitudinal portion (33).

In selected embodiments, the fasteners (330, 331) of the longitudinalportion (33) include a fixing stop (331) with an outside diameter thatis greater than that of the hollow tubes (34).

The present invention also provides various processes for thepreparation of a vertebral support device having a dampening element,such as various embodiments of the present invention described herein.In such processes, the tension of one or more components of a dampeningelement is adjusted before the implantation of the device in accordancewith the particular requirements of the implantation. The processesgenerally comprise the following steps:

-   -   placing a central portion of the dampening element between rigid        elements of the dampening element;    -   placing a longitudinal portion of the dampening element along        the rigid elements of the dampening element;    -   adjusting the tension of the longitudinal portion of the damping        element; and    -   fixing the longitudinal portion of the damping element in        relation to the rigid elements of the dampening element.

In selected embodiments, the step of adjusting the tension of thelongitudinal portion (33) is accompanied by a step of marking of atleast one tension mark close to at least one of the ends of thelongitudinal portion.

In selected embodiments, the step of fixing of the longitudinal portion(33) in relation to the rigid elements (34) by means of the fasteners(330, 331) includes a step of clamping of at least one end of thelongitudinal portion (33) by a removable lock, staple, ring, clip, pin,or stitch (330).

In selected embodiments, the steps of adjusting the tension and forfixing of the longitudinal portion (33) includes a step of inserting atleast one removable lock (300) in at least one hole drilled in thelongitudinal portion (33), along an axis that is substantiallyperpendicular to the longitudinal axis (L), where this hole constitutesa tension mark that is used to determine the tension of the longitudinalportion (33).

In selected embodiments, the step of placement of the longitudinalportion along the rigid elements comprises a step of insertion of thelongitudinal portion inside a groove, channel, or chute of the rigidelements.

In selected embodiments, the step of insertion of the longitudinalportion inside a groove, channel, or chute of the rigid elements isassociated with a step of insertion of the longitudinal portion inside ahole extending the groove, channel, or chute at the fixation end of therigid elements (34) at the level of the fasteners, such as clamps (20).

In selected embodiments, the step of placement of the longitudinalportion in relation to the rigid elements (34) comprises a step ofinsertion of the longitudinal portion inside a conduit of the rigidelements (34) which comprise hollow tubes and inside a conduit of thecentral portion, which is also hollow.

In selected embodiments, the step of fixing the longitudinal portion(33) includes a step of setting, on the end of the longitudinal portion(33) opposite to that including the removable locks, staples, rings,clips, pins, or stitches (330), a fixing stop (331) having an outsidediameter that is greater than that of the hollow tubes (34).

In selected embodiments, the step of placement of the longitudinalportion in relation to the rigid elements comprises a step of insertionof the rigid elements, comprising solid bars, and of the centralportion, inside the longitudinal portion (33) comprising an elasticsheath or sleeve.

In selected embodiments, the method comprises a step of adjustment ofthe position, along the longitudinal axis (L), of the rigid elements(34) with respect to the implants (2), followed by a step of blockingthe rigid elements at the desired position by fasteners such as clamps(20).

In selected embodiments, the method comprises a step of adjustment ofthe orientation of the longitudinal axis (L) of the rigid elements withrespect to the axis of the spinal column, followed by a step of blockingthe rigid elements at the desired orientation by fasteners such asclamps (20).

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS:

The features and advantages of various embodiments and various aspectsof the present invention will appear more clearly to those of skill inthe art on reading the description that follows, with reference to theappended drawings in which:

FIG. 1 shows a perspective view of one embodiment of a vertebral supportdevice according to the invention;

FIG. 2 shows a longitudinal cross sectional view of one embodiment of avertebral support device according to the invention;

FIG. 3A shows a perspective view of one embodiment of a vertebralsupport device according to the invention, and FIG. 3B shows a crosssection view of the linking element shown in FIG. 3A;

FIGS. 4A, 4B, and 4C show longitudinal cross sectional views of threedifferent embodiments of the linking element of a vertebral supportdevice according to the invention;

FIGS. 5A and 5B show longitudinal cross sectional views of two differentembodiments of the linking element of a vertebral support deviceaccording to the invention, and FIG. 5C shows a longitudinal crosssectional view of a central portion of the dampening element shown inFIG. 5B;

FIG. 6A shows an elevation view of one embodiment of a vertebral supportdevice according to the invention, and FIGS. 6B and 6C show two of themany different embodiments of rigid elements configured according to theinvention;

FIGS. 7A and 7B show longitudinal cross sectional views of two differentembodiments of a vertebral support device according to the invention;

FIG. 8A shows a perspective view of one embodiment of a vertebralsupport device according to the invention, FIGS. 8B and 8C show,respectively, a perspective view and a longitudinal cross sectional viewof one embodiment of a linking element of a vertebral support device,and FIGS. 8D and 8E show, respectively, a perspective view and alongitudinal cross sectional view of the linking element shown in FIG.8A;

FIG. 9 shows a longitudinal cross sectional view of an embodiment of avertebral support device according to the invention, with the device ina bent position;

FIGS. 10A and 10B show, respectively, an elevation view and alongitudinal cross sectional view of another embodiment of a vertebralsupport device according to the invention, and FIG. 10C shows aperspective view of one of the various types of rigid elements that canbe used in this embodiment;

FIGS. 11A and 11 B show, respectively, an elevation view and alongitudinal cross sectional view of another embodiment of a vertebralsupport device according to the invention, and FIG. 11C shows aperspective view of one of the various types of rigid elements that canbe used in this embodiment; and

FIGS. 12A and 12B show, respectively, an elevation view and alongitudinal cross sectional view of an embodiment of a linking elementthat can be used in various embodiments of a vertebral support deviceaccording to the invention, the linking element comprising rigidelements disposed within the longitudinal elastic portions, and

FIGS. 12C and 12D show, respectively, an elevation view and alongitudinal cross sectional view of another embodiment of a linkingelement that can be used in various embodiments of a vertebral supportdevice according to the invention, in which the rigid elements aredisposed within the longitudinal elastic portion;

FIGS. 13A and 13B show, respectively, a perspective view and alongitudinal cross sectional view of an embodiment of linking elementthat can be used in various embodiments of a vertebral support deviceaccording to the invention, the linking element comprising rigidelements disposed within the longitudinal elastic portion;

FIGS. 14A and 14B show, respectively, a longitudinal cross sectionalview and a perspective view of two embodiments of a vertebral supportdevice according to the invention in which the linking element comprisestwo dampening elements;

FIG. 15A shows a perspective view of an optional embodiment of rigidelement for a linking element that can be used in various embodiments ofa vertebral support device according to the invention, the rigid elementcomprising a longitudinal slit allowing the compression of thelongitudinal portion when a fastener is tightened, and

FIGS. 15B and 15C show, respectively, an elevation view and alongitudinal cross sectional view, of part of a vertebral support devicecomprising an embodiment of a linking element according to FIG. 15A;

FIG. 16 shows a perspective view of an embodiment of a vertebral supportdevice according to the invention in which each of the implantscomprises a hook for attachment to the vertebrae;

FIG. 17 shows a perspective view of an embodiment of a vertebral supportdevice according to the invention having double-fixing implants fixingtwo linking elements substantially parallel to each other;

FIGS. 18A and 18B show, respectively, a upper view and a longitudinalcross sectional view of an embodiment of a vertebral support deviceaccording to the invention having double-fixing implants fixing twolinking elements substantially collinear to each other;

FIGS. 19A, 19B, 19C and 19D show, respectively, a perspective view, aside view and two detail views of 4 embodiments of weave or braids of adampening element of a vertebral support device according to theinvention;

FIG. 20 show a perspective view of two adjacent vertebrae on which anembodiment of a vertebral support device according to the invention ismounted, wherein the dampening element is centered with the articularprocesses of the two vertebrae;

FIG. 21 show a perspective view of two adjacent vertebrae on which anembodiment of a vertebral support device according to the invention ismounted, wherein the dampening element is centered with theintervertebral space between the two vertebrae.

DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS:

This present invention concerns a vertebral support device such as, forexample, the various embodiments of a device (1) as illustrated in FIGS.1, 3A, 6A, 7A, 7B, 8A, 9, 10A, 10B, 11A, and 11B. The vertebral supportdevices of various embodiments of the invention are configured forimplantation on at least two vertebrae, which may be adjacent or moreremote, and are used to support these vertebrae in a given position,established during the implantation of the device, while still leavingthese vertebrae with a certain freedom of movement about this position.A vertebral support device (1) according to certain embodiments of theinvention includes at least two osseous anchoring implants (2), eachdesigned to be anchored to a vertebra. Often, each implant (2) isanchored to the pedicles of a vertebra along an axis called adorso-ventral (DV) axis. A dorso-ventral (DV) axis is generally orientedalong the dorso-ventral axis of the vertebra, which also can be calledan antero-posterior or sagittal axis, depending on the nomenclatureemployed. Accordingly, the insertion axis along which an implant (2) isanchored to a vertebra will be referred to herein as a “dorso-ventralaxis (DV).” However, embodiments having different implantation locationsand anchorage angles are within the scope of the invention, and those ofskill in the art will recognize that such nomenclature is adopted solelyfor convenience of description and does not limit the scope of inventionto implants anchored at any particular place or in any particularorientation.

A vertebral support device (1) according to certain embodiments of theinvention also includes at least one linking element (3) attached toimplants (2). In many embodiments, linking element (3) comprises atleast two rigid elements (34) articulated by at least one elasticdampening element (31). A wide variety of embodiments of linkingelements is within the scope of the invention, including withoutlimitation those described here. For example, the linking element (3)may comprise one or several dampening elements (31) and one or severalrigid elements (34) attached to the implants (2). Various embodimentswithin the scope of the invention may have a dampening element (31)comprising, depending on the embodiments, at least one elastic centralportion (32) absorbing the compression stresses applied on the device(1) and/or at least one elastic longitudinal portion (33) absorbing theextension or flexion stresses applied on the device (1). In variousembodiments, rigid elements (34) of linking element (3) are fastened toimplants (2) by fasteners (20). Many embodiments use clamps, such asclamps (20) illustrated in FIGS. 2, 6A, 9, 10B, and 11 B, but otherfasteners that generally can be used to fasten rods to vertebralanchoring implants may be substituted, as discussed further below.Various embodiments of the invention can include plural linking elements(3). For example, linking elements (3) can be generally parallel to eachother to support two vertebrae on either side of the sagittal plane, orbe aligned to support several successive adjacent vertebrae, as will beexplained later.

Linking element (3) can have any elongated shape. Regardless of itsshape, linking element (3) can be considered to comprise a dorsal face(or surface), a ventral face (or surface), and two lateral faces (orsurfaces) with respect to a device (1) that is implanted along thedorsal faces of the vertebrae, even if the linking element does notnecessarily comprises 4 faces (or surfaces). A device (1) within thescope of the present invention can also be implanted along the ventralfaces of the vertebrae, but such installation generally is not preferreddue to the presence of large blood vessels. Accordingly, the directionalreferences used herein, including the foregoing as well as references tovarious planes such as the frontal plane and the sagittal plane, arespecified with reference to a device (1) installed along the dorsalfaces of the vertebrae. Those of skill in the art readily willappreciate the appropriate adjustments for directional references withrespect to a device (1) implanted along the ventral faces of thevertebrae or elsewhere. Thus, a reference to a dorsal, a ventral, or alateral face for surface of a component is solely a reference to anexterior part of the component having an orientation consistent with aframe of reference for a device (1) installed along the dorsal faces ofthe vertebrae.

The linking element (3) generally can be considered to have a“longitudinal axis (L)” since it links implants (2) and comprises atleast one dampening element (31). This specification uses thenomenclature “longitudinal axis” as a general and nonlimiting referenceto a direction in which an elongated object is elongated. For example,the linking element (3) generally can be considered to have a“longitudinal axis (L)” corresponding to its direction of its elongationit is in a “neutral” or “at rest” position, to the intended normalposition of the vertebrae (i.e., no flexion, extension, lateral bending,rotation, or other displacement of the vertebrae) along which device (1)is (or will be) installed. In many implantations, longitudinal axis (L)will be oriented along the axis of the spinal column, but the linkingelement (3) may be disposed in other orientations. By way of nonlimitingexample, the vertebrae generally follow a natural or pathological curve,and linking element (3) may be oriented in accordance with a naturalcurve or in accordance with correction of a pathological curve. Inaddition, the nomenclature “longitudinal axis” is not necessarilylimited to a single, static linear direction. For example, as discussedbelow the linking element (3) can be installed having a neutral positionin which the linking element (3) is bent in its neutral position, in maybe considered to have a “longitudinal axis” corresponding generally tothe bend or to have a localized “longitudinal axis” in various areas,such as, for example, one or both of the rigid elements (34) or thedampening element (31).

Articulation of the rigid elements (34) by the dampening element (31)offers, in many embodiments, a certain degree of freedom of movement tothe patient on which the device (1) is implanted, absorbing the stressesexperienced by the linking element (3) during these movement and tendingto return the device (1) to its neutral position. In variousembodiments, dampening element (31) comprises at least one centralelastic portion (32) located between the two rigid elements (34) andcooperating with them to absorb compressive and other stresses andstrains imposed on the linking element (3). The articulation of the tworigid elements (34) occurs about central elastic portion (32), which islocated between the rigid elements. Alternative embodiment of a linkingelement (3) could include several dampening elements (31) located atgiven distances from each of the osseous anchoring implants (2), so asto still further increase the freedom of movement, in particularregarding torsion of the spinal column. Various embodiments of linkingelements (3) may have multiple dampening elements. FIGS. 14A, 14B, and16 show two non-limitative examples of possible embodiments of a device(1) including such a linking element (3) comprising two dampeningelements (31). Many other variants and optional embodiments of multipledampening elements (31) are possible within the scope of the invention,such as, for non-limiting example, embodiments having different types ofdampening elements and embodiments having varying positions of thevarious dampening elements (31) along the longitudinal axis (L) of thelinking element (3).

The dampening element (31) also comprises, in exemplary embodiments, alongitudinal elastic portion (33) comprising two ends configured toabsorb the stresses occurring on the linking element (3). In variousembodiments, the ends of the longitudinal elastic portion (33) are fixedwith respect to the implants (2) and/or the rigid elements (34) byfasteners (330, 331). Elastic forces of the central (32) andlongitudinal (33) portions oppose to each other, facilitating support ofthe vertebrae while allowing the vertebra some freedom of movement andtending to return the vertebrae to the rest position.

In various embodiments of the invention, dampening element (31) will becomposed of a weave (or a braid) of synthetic fibers. These particularlyadvantageous embodiments can facilitate accommodation by the dampeningelement (31) of the stresses and strains imposed by movement of thevertebrae on which device (1) is attached and adjustment of the tensionof dampening element (31) at rest in the device (1) as explained below.The stitches of this weave or the plaits of this braid can be tightenedto varying degrees to adjust the elastic properties of the dampeningelement (31) according to a desired elasticity. The dampening element(31) of these embodiments also can be stitched, which can facilitateassembly of its constituting parts and/or its fixation to the rest ofthe device. Alternatively, the dampening element (31) can be configuredfrom solid elastic material having characteristics suitable foraccommodation of the stresses and strains imposed by movement of thevertebrae on which device (1) is attached and adjustment of the tensionof dampening element (31) at rest in the device (1). Such an elasticmaterial also can eventually be stitched for assembly in the deviceand/or for adjustment of its tension. Of course, the central (32) andlongitudinal (33) portions can be realized in the same weave, braid, orsolid material, as described below, but can also be realized with anycombination of the materials described here or any equivalent materialthat is flexible or elastic. In addition, in some embodiments describedbelow, the dampening element (31) will not necessarily be in directcontact with the surrounding tissue and thus can be made fromnon-biocompatible material, but in preferred embodiments a biocompatiblematerial will be used. FIGS. 19A, 19B, 19C and 19D depict non-limitativeexamples of such braids or weaves.

In some embodiments of the invention, the longitudinal portion (33) andthe central portion (32) are formed as a unit. In some of theseembodiments, the junctions between the central portion (32) and thelongitudinal portion (33) of the dampening element (31) formreceptacles, each receiving one end of one of the rigid elements (34),as shown for example in FIGS. 3B and 4A where the rigid elements (34)are hollow tubes. The central portion (32) and the longitudinal portion(33) of the dampening element (31) in some of these embodimentscollectively can comprise a single weave or braid of synthetic fibers,in which the size of the links of the weave or of the plaits of thebraid is substantially identical in the two portions (32 and 33), whichtherefore have the same elastic properties. In other embodiments, theelastic properties of the central portion (32) and of the longitudinalportion (33) of the dampening element (31) can be different, althoughthey form a single weave or braid of synthetic fibers, by varying thetightness of the links of the weave or of the plaits of the braid thetwo portions (32 and 33), or their size. Alternatively, the unit can beformed from a single block of solid elastic material, or can beconstructed by fixing together a central portion (32) and a longitudinalportion (33) each comprising solid elastic material. Alternatively, theunit can comprise one component made of a weave or braid of syntheticfibers and another component made of solid elastic material. In thesealternatives, the components can have elastic properties that aresimilar or not, depending on whether the components are connectedtogether in a single block, by stitching or any other means, or onwhether the components are constructed with different elasticproperties.

In some embodiments, such as shown in FIGS. 2, 4B, 4C, and others, thecentral portion (32) and the longitudinal portion (33) of the dampeningelement (31) are two discrete elements. In some embodiments, the centralportion (32) is hollow and has an inside diameter that is substantiallyidentical to the outside diameter of the longitudinal portion (33).Thus, the central portion (32) mainly accommodates the compressionstresses applied to the linking element (3), and the longitudinalportion (33) mainly accommodates the extension and torsion stressesapplied to the linking element (3). Such stresses result, for example,from bending of the linking element (3) being damped by these twoportions (32 and 33), as shown in FIG. 9. In a variant of thisembodiment, the central portion (32) and the longitudinal portion (33)of the dampening element (31) will each be composed of a weave or braidof synthetic fibers, with the size of the links of the weave or of theplaits of the braid being substantially identical on the two portions(32 and 33) which therefore have the same elastic properties. In anothervariant, the elastic properties of the central portion (32) and of thelongitudinal portion (33) of the dampening element (31) are different,due to a weave or braid that varies in the degree of tightness of thetwo portions (32 and 33). As previously, these two portions can bestitched together, regardless of the size of the links or of the braidsof the synthetic fibers.

In the embodiments shown for example in FIGS. 4A and 4B, the insidediameter of the central portion (32) and the outside diameter of thelongitudinal portion (33) are substantially identical to the insidediameter of the hollow tubes (34) of the linking element (3).Alternatively, the inside diameter of the central portion (32) can besmaller than the inside diameter of the hollow tubes (34) of the linkingelement (3), with the outside diameter of the longitudinal portion (33),at the central portion (32), being substantially identical to the insidediameter of the central portion (32) and, at the hollow tubes (34),being substantially identical to the inside diameter of the hollow tubes(34). During severe compression stresses, this alternative inhibits theinside edge of the ends of the hollow tubes (34) from sliding betweenthe outer surface of the longitudinal portion (33) and the inner surfaceof the central portion (32).

Rigid elements (34) of the linking element (3) can comprise bars, tubes,rods, rails, or similar structures, whether straight or not, havingcylindrical, polygonal, or other cross section, or indeed of any type ofrigid structure adapted to the morphology of the spinal column of thepatient on which the device is intended to be implanted. In someembodiments, a rigid element (34) includes at least one surface (340)configured to cooperate with a fastener fixing the rigid element (34) toan implant (2) to prevent rotation of the linking element (3) around itslongitudinal axis (L). For example, FIG. 6A shows a flat surface, “flat(340),” on which a corresponding flat surface of clamp (20) bears. Invarious embodiments, flat (340) can be present on the entire dorsalsurfaces of the rigid elements (34) or only on a part at which the rigidelements (34) are fastened to the implants (2) by means of the fastenerssuch as clamps (20). As shown in the figures, the fasteners (20) can belocated on the implants (2) in order to fix the linking element (3) andallow an adjustment of the position, along the longitudinal axis (L), ofthe linking element (3) with respect to the implants (2). In addition,surface (340) can be configured in other geometries wherein cooperationof that surface with the fastener will prevent axial rotation of rigidelement (34) about its longitudinal axis. The fixation of the linkingelement (3) to the implants (2) along rigid elements (34) reduces therisk of damage to linking element (3), compared to a direct fixation ofthe dampening element (31) to the implants (2).

In some embodiments of the invention, the rigid elements (34) of thelinking element (3) can be tubes (34), each connected to an osseousanchoring implant (2) by the fasteners (20) and articulated by thedampening element (31) about a central portion (32) that fits onto eachof the two tubes (34). The central portion (32) of the dampening element(31) can have an outside diameter that is about equal to the outsidediameter of the tubes (34) of the linking element (3), but preferablythe outside diameter will be greater to improve handling of thecompressive stress imposed by the tubes (34), particularly when suchstresses are not applied along an axis that is collinear with thelongitudinal axis (L) of the linking element (3). Thus, in manyadvantageous embodiments, the central portion (32) of the dampeningelement (31) has an outside diameter that is, to varying degrees, largerthan the outside diameter of the tubes (34) of the linking element (3).

In various embodiments of the invention, the rigid elements (34) of thelinking element (3) are hollow and include an internal channel orconduit in which longitudinal portion (33) is mounted or otherwisedisposed. In some embodiments, the channel or conduit and thelongitudinal portion (33) preferably will be substantially cylindrical,but other geometries are possible, for example, a rectangular crosssection that inhibits bending of the linking element (3) along itslateral surfaces. The longitudinal portion (33) may have an outsidediameter or size that is substantially equal to the inside diameter orsize of the channel or conduit in the rigid elements (34), or an outsidediameter or size less than the inside diameter or size of the channelconduit to facilitate movement of the longitudinal portion (33) in therigid elements (34) and handling of the stresses in extension (amongstothers) applied to the linking element (3).

In some embodiments, the rigid elements (34) can comprise solid bars.For some of these embodiments, longitudinal portion (33) can be disposedalong these bars, or inserted in a groove (or chute) longitudinallylocated on a surface of the bars, for example as described later inreference to FIGS. 10(A to C) and 11(A to C). In other embodiments, forexample as illustrated in FIGS. 12A through 12D, bars (34) can beinserted inside an elastic longitudinal portion (33) that surrounds therigid elements (34) and the central portion (32) much like a sheath. Aswith other embodiments, the central (32) and longitudinal portion (33)can be a single piece or plural separate pieces. The rigid elements (34)and the central portion (32) can be attached or not, with thelongitudinal portion (33) being attached to the rigid elements (34), forexample as detailed later in reference to FIGS. 12(A to D). If notattached together, central portion (32) and the rigid elements (34)nevertheless can be held together by the longitudinal portion (33)surrounding them, or central portion (32) and the rigid elements (34)can be attached by any mean, such as glue, threaded fastener, rivet,tongue and groove, or other connectors. In these embodiments, thelongitudinal portion (33) can be maintained in tension and fixed to therigid elements (34) by fasteners (330, 331), for example as describedlater. In other embodiments not shown, this longitudinal portion (33) ofthe linking element (3) can have a length that is substantiallyidentical or slightly less than that of the assembly formed by thelinking element (3) and can include, at its ends, fasteners inside thetubes, such as glue, threaded fastener, compression of its ends or anyother fastener able to attach these ends solidly to the rigid elements(34).

In some embodiments of the invention, as shown in FIGS. 6B and 6C, therigid elements (34) are tubes open over at least one part of theirlength, for example to facilitate the insertion of the longitudinalportion (33) inside the tubes (34). The opening of the tubes (34) makesa transverse cross section generally having the shape of a “U” if thetubes are cylindrical or have a polygonal cross section. The opening ofthe “U” enables the insertion of the longitudinal portion (33) which canthen be fixed, for example by fasteners (330, 331), with respect to thetube. In the embodiment shown in FIG. 6C, the hollow tube (34) is notopen along its entire length and the closed portion can act cooperatewith a fastener (330, 331). The closed portion also can comprise a flat(340) as shown or another type of surface cooperative with a fastener,for example clamp (20), fixing the rigid element (34) to an implant (2).

In the embodiment shown in FIG. 6B, the hollow tube (34) is opened alongits entire length, and one of its extremities can cooperate with thefastener (330, 331) of the longitudinal portion (33). In the embodimentillustrated in FIG. 6B, the edges of the longitudinal opening form asubstantially flat surface configured to cooperate with a fastener, forexample clamp (20), fixing the rigid element (34) to an implant (2). Inmany of the embodiments, the longitudinal portion (33) of the linkingelement (3) has a length that is greater than the aggregate length ofthe two tubes (34) and the central portion (32), and the ends of thelongitudinal portion (33), protruding from the rigid element (34) arefixed in relation to the tubes (34) by fasteners (330, 331). In certainembodiments, the tension of the elastic longitudinal portion (33) can beadjusted by adjustment of the relative position of the fasteners (330,331) with respect to the elastic longitudinal portion (33). Thus, theposition of at least one of the fasteners (330, 331) can be adjusted inthe factory (with relatively precise measurement of the tension) or atthe operating table by the surgeon, who can adjust the tension accordingto the configuration of the vertebrae on which the device is implanted.

In an embodiments such as shown in FIG. 1, for example, the fasteners(330, 331) can comprise at least one removable lock, staple, ring, clip,pin, or stitch (330), clamping at least one end of the longitudinalportion (33). In these embodiments, the ends of the longitudinal portion(33) can protrude from one or both ends of the hollow tubes (34), or canterminate within one or both of the tubes (34). FIG. 1, for example,shows a staple (330), but alternatives include structures such as a ringtightened around the end of the longitudinal portion (33) or any otherremovable lock, clip, pin, stitch or other fastener that can engage theend of the longitudinal portion (33) after its assembly with the rest ofthe device (1). For example, in some embodiments in which the rigidelements are hollow tubes (34), the fasteners (330, 331) for thelongitudinal portion (33) can include at least one removable lock (330)that fits into at least one hole (330 a) extending transversally throughthe longitudinal portion (33), along an axis that is substantiallyperpendicular to the longitudinal axis (L). The hole (330 a) can be atension mark used to determine the tension of the longitudinal portion(33), as shown for example on FIGS. 8A, 8D and 8E. The lock (330) cancomprise lock, staple, ring, clip, pin, or stitch to be inserted intothe hole, or other types of fasteners. A pin can be flared at its endsor fitted at its ends with stops to prevent it from leaving the hole, orits ends can include threads to mount a nut, or the pin can include anytype of structure enabling it to be locked effectively in a given holeof the longitudinal portion (33) and thus maintain the latter intension. Removable fasteners (330) also may comprise a stitching, suchas a wire or filament passing through a hole (330 a) extendingtransversally through the longitudinal portion (33) and passing throughholes (or drilling) (330 b) made in the rigid elements (34), as shown inFIGS. 8A, 8D and 8E. Those of skill in the art will recognize that theterm “hole” or “drilling” can designate any type of channel passingthrough the longitudinal portion (33). The two ends of the longitudinalportion (33) can be equipped with this type of removable fastener, asshown in FIG. 4A, but a removable fastener (330) also can be used on oneend only, in association with a non-removable lock (331) on the otherend, such as a fixing stop for example. Thus, in some variantembodiments, the fasteners (330, 331) for the longitudinal portion (33)will include, at the end of the longitudinal portion (33) opposite tothat which includes the removable fastener (330), a fixing stop (331)that comprises a widening of the longitudinal portion (33), where thisfixing stop (331) has an outside diameter that is greater than that ofthe hollow tubes (34), as shown in FIGS. 1, 2 and 3A for example.

In the embodiments comprising a longitudinal portion (33) having alength greater than the aggregate length of the rigid elements (34) andthe central portion (32), and extending beyond the extremities of thetubes, adjustment of the tension is facilitated by the fact that thetension varies as a function of the length of the longitudinal portion(33) extending beyond the extremities of the rigid elements (34)(whether hollow or solid). Nevertheless, the longitudinal portion canhave a length adapted not to extend beyond the length of the rigidelements (34). In some embodiments, the rigid elements (34) can compriseholes (or bores or drillings) (330 b), as shown in FIGS. 8D and 8E, withfasteners (330, 331) being configured for insertion in such holes toclamp the longitudinal portion (33) after adjustment of its length (andthus of its tension). For example, when the rigid elements (34) arehollow tubes in which the longitudinal portion (33) is inserted, or whenthe rigid elements (34) are solid bars along which a sheath-likelongitudinal portion (33) is disposed, fasteners (330) typically willpenetrate the longitudinal portion (33) and the rigid element (34) tofix the longitudinal portion (33) to the rigid element (34).Furthermore, to allow adjustment of the tension, the elasticlongitudinal portion (33) can include, in some embodiments of theinvention, at least one tension mark used to identify at least oneposition at which the fasteners (330, 331) of the longitudinal portion(33) must be placed along the longitudinal portion (33), by pulling(stretching) the longitudinal portion, in order to achieve at least onegiven tension. Such tension mark typically will be close to at least oneof end of the longitudinal portion (33), and may comprise, for example,marks or notches visible at the surface of the longitudinal portion whenthe latter extended beyond the extremities of the rigid elements(whether hollow or solid). In the embodiments in which the rigidelements are hollow tubes, the tension marks may also comprise holesextending transversally through the longitudinal portion (33),regardless of whether the longitudinal portion (33) is configured toextend beyond the extremities of the tubes (34). These holes will thenenable the insertion of the fasteners (330, 331) through thelongitudinal portion (33) for its fixation and for adjustment of itstension.

In other embodiments, the ends of the longitudinal portion (33) eachinclude a fixing stop (331) as shown in FIG. 3B. Factory configureddevices (1) are particularly well suited to be equipped with fixingstops (331) at each end, and tension of the longitudinal portion (33)can be set during the assembly of the device (1) in the factory. Inother embodiments, the ends of the longitudinal element (33) eachcomprise a fixing stop (331), and the rigid elements (34) are hollowtubes with a U-shape section as described previously for facilitatingthe assembly of the device. For such embodiments, the tension can be setat the factory by the location of the fixing stops (331), and thepredetermined tension will be achieved upon assembly when thelongitudinal portion (33) is inserted in the tubes (34), which can occurin the factory or in the surgical suite.

Implants (2) can take many forms such as, for example, the vertebralanchoring implants described in patent applications WO03/049629 and WO2005/020829, submitted by the assignee of the present application, orother types of bone-anchoring implant such as, for example, thosediscussed in patent applications EP 0572790 or WO 00/15125 or patentU.S. Pat. No. 5,501,684, or other configurations that are suitable foranchoring to a vertebra and holding a bar (or any linking element)securely. Patent applications EP 0572790 and WO 00/15125 and patent U.S.Pat. No. 5,501,684 are incorporated herein by reference for allpurposes. These different bone-anchoring implants (2) include anchors(21) such as a screw (21) intended to be screwed into a vertebra or ahook (21) intended to be inserted into suitable shapes on the vertebraeor recesses made especially in the vertebrae. FIG. 16 depicts anon-limitative example of a device (1) in which each of the implants (2)comprises a hook for anchoring, although alternative embodiments mayhave differing types of anchors, for example a device (1) comprising animplant having a screw and an implant having a hook. This type of hookis described in detail in reference to FIG. 7 of PCT Publication No. WO03/049629 and to FIG. 4 of PCT Publication No. WO 2005/020829.

As noted above, the implantation axis of the implants (2) often issubstantially parallel to the dorso-ventral axis of the vertebrae.Another implantation axis (DV), however, may be preferred in someinstallations (which, as discussed above, still may be referred toherein as a dorso-ventral (DV) axis), in which polyaxial osseousanchoring implants (2) such as, for example, those described in patentapplications WO03/049629, WO 00/15125 and WO 2005/020829 may be used toadvantage. Polyaxial osseous anchoring implants may allow use of thedevice (1) irrespective of the angle between anchoring axis (DV) of theimplants (2) and longitudinal axis (L) of linking element (3). Polyaxialimplants (2) also may be used to advantage for orientations oflongitudinal axis (L) of linking element (3) other than along the axisof the spinal column. Thus, as mentioned previously, the fixation of thelinking element (3) can be realized so that it follows the natural orpathological curve of the spinal column. In many of the embodiments ofthe invention, the angle between a longitudinal (L) axis of the linkingelement (3) in relation to the dorso-ventral (DV) axis of the implants(2) is fixed, after fixing the linking element (3) with the clamps (20)of the implants (2), regardless of the actual orientations of thelongitudinal (L) and dorso-ventral (DV) axis (along the axis of thespinal column or not and, respectively, along the antero-posterior axisof the vertebrae or not). When such fixed angle is imposed, thedampening element (31) accommodates the stresses imposed on the assemblyby movement of the vertebrae regardless of the orientations of theanchoring axes (DV) of the implants (2) or the longitudinal axis (L) ofthe linking element (3) and allows maintenance or restoration of thespace between the vertebrae between which the device is implanted.Polyaxial implants may also be devised to permit some freedom ofmovement or the rod (or bar), even after the rod (or bar) is clamped tothe implants. Such types of implants can be used within the scope of theinstant invention, alone or in combination with other types of implants.For example, some embodiments may have each of the rigid elements (34)of the linking element (3) fixed to an implant (2) that allows somefreedom of movement after the rigid element is clamped by the clamp(20). For another example, some embodiments may have one or more of therigid elements (34) of the linking element (3) fixed to an implant (2)that allows some freedom of movement after the rigid element (34) isclamped by the clamp (20), with one or more of the other rigid elements(34) of the linking element (3) fixed to an implant (2) that imposes afixed angle between a longitudinal (L) axis of the linking element (3)and the dorso-ventral (DV) axis of the implant (2) after the after therigid element (34) is clamped by the clamp (20). In this example, thedevice (1) could still maintain or restore a space between the vertebraeon which it is implanted, but may allow more freedom of movement.

As shown in the figures, the osseous anchoring implants (2) includeanchors (21) that are used to attach the implants (2) to the vertebrae.The implant (2) includes a conduit (22) configured to accept the linkingelement (3) and with fasteners, such as clamps (20), for fixing thelinking element (3) against an internal wall of the conduit (22). Thefasteners (20) generally can be a driven coupler, such as a screw, forexample, or any type of known element that can secure linking element(3) to the implant (2). Each fastener (20) holds a rigid element (34)such that the longitudinal axis (L) of the linking element (3) extendingthrough the rigid element (34) and the axis (DV) along which implant (2)is anchored to the vertebra establish a fixed angle. The fasteners, suchas clamps (20) shown in the figures, can comprise a fixing screw thatincludes a flat at its base, intended to be in contact with the flat(340) on the linking element (3). As described in patent applicationsWO03/049629 and WO 2005/020829 incorporated herein, clamp (20) cancomprise a ball and socket connection at its base, and/or the conduit(22) of the implant (2) receiving the linking element (3) can be flaredand/or comprise a mobile baseplate. Structures such as these can providea certain degree of freedom to the linking element (3) with respect tothe implant (2) before their fixation. In many embodiments, the flat(340) is present on the dorsal surface of the linking element (3), sincethe clamps (20) are substantially collinear with the axis (DV) of theimplants and rest against this dorsal surface of the linking element,but the flat (340) can be located differently according to theconfiguration of the clamps (20) or may not even be necessary. Clamps(20) can comprise a recess or a projection for engagement with a toolfor tightening the clamps (20), such as, for example, a six-sided holeor stud, or a groove of a screw or a nut. Any type of fastener used tosecure an implant to a link, either on the implant or on the link, canbe used in alternative embodiments of the invention, to the extent thatthese fasteners allow a constant angle to be maintained between thelongitudinal axis (L) of the linking element (3) passing through a rigidelement (34) and the axis (DV) of the implant (2) to which the rigidelement (34) is secured. The embodiments represented in the figures areparticularly advantageous, since they use implants (2) of previousdesigns that facilitate the fitting of the device (1) by means of thedegrees of freedom conferred by the clamps (20) before tightening andallow adjustment of the orientation of the rigid elements (34) asmentioned previously.

From the foregoing discussion, those of skill in the art will recognizethat the dampening element (31) allows the device (1) to maintain theposition of the implants (2) in relation to each other, while stillproviding some freedom of movement to the implants (2). Because of thedampening element (31), the support provided by the device (1) invarious embodiments is relatively flexible and allows the vertebrae tobe held in a desired position, thus offering relief to theintervertebral disc, while still leaving freedom of movement to thepatient on which the device (1) is intended to be implanted.

The cooperation of the central portion (32) and of the rigid elements(34) also allows the distance between the vertebrae to be maintained,thus providing space between the vertebrae. This space, of course, canbe substantially equal to the natural space between the vertebrae atrest, but if desired the space can be enlarged or reduced, even if thedevice is already implanted on the vertebrae, by enlightening the clamps(20), by separating or gathering the vertebrae with known tools, byadjusting the position of the rigid elements (34), and then byretightening the clamps (20).

In addition, fastening rigid elements (34) to implants (2) allows, inmany embodiments, imposition of particular orientations on the linkingelement (3), unlike some other types of flexible support devices. Thus,for example, the linking element (3) can be installed having a neutralposition in which the elastic dampening element (31) exerts a permanentforce on the vertebrae when at rest, which in some embodiments isachieved by linking element (3) being bent in its neutral position. Thisaspect of various embodiments can facilitate accurate fitting of device(1) to the curve of the spinal column or correction of defects in thepositions of the vertebrae.

Adjustable fixation of the rigid elements (34) to the implants (2) canprovide additional advantages in various embodiments. For example, thelength and position of the rigid elements (34) with respect to theimplants (2) can be adjusted to vary the position of the articulation ofthe rigid elements (34) provided by the dampening element (31).Articulation can be centered, as illustrated respectively in FIGS. 21and 20, with respect to the intervertebral space (IV) or with respect tothe articular processes (AP) of the vertebrae, which is located lowerthan the center between the vertebral bodies. Other articulationpositions may be preferred in some embodiments.

In various embodiment of the invention, the dampening element (31) islocated on the longitudinal axis (L) of the linking element (3)substantially equally distant from each of the implants (2) betweenwhich it is located, thus centering the dampening element (31) betweenthe implants (2). However, linking element (3) can have an off-centerdampening element (31), as shown in FIG. 5A, which may be advantageousto adapt to the morphology of the patient on which the device (1) isimplanted, and to optimize the stresses applied to the dampening element(31). Indeed, as mentioned previously, the articulation of the linkingelement (3) can be centered, for example, with respect to the articularprocesses (AP) rather than with respect to space (IV) between thevertebral bodies. In many embodiments, rigid elements (34) can have avariable length as illustrated in the non-limitative example of FIG. 5Aand/or a variable position with respect to the implants, which allowsadjustment of the position of the dampening element (31) with respect tothe vertebrae. FIGS. 20 and 21 show two non-limitative examples of anembodiment of the device implanted on two adjacent vertebrae. In theexample of FIG. 20, the dampening element (31) is centered relative tothe articular processes (AP) between the vertebrae, whereas in FIG. 21,the dampening element (31) is centered relative to the intervertebralspace (IV) between the vertebrae. Those of normal skill in the art willof course understand by reading the instant specification that theinvention allows an adjustment of the different elements of the device(1) at any desired position and with any desired orientation and thatthe FIGS. 20 and 21 are given here only as illustrative examples.

Various embodiments can have rigid elements (34) configured withelongated regions suitable for engagement with fasteners (20) to fix therigid elements (34) to the implants (2). By varying the point at whichthe rigid elements (34) are fixed to the implants (2), the position ofthe linking element (3) with respect to the vertebrae can be adjustedduring the implantation of the device (1).

In the embodiment shown in FIG. 4C, for example, the central portion(32) includes, on either side of its centre along the longitudinal axis(L), a chamfer (321) facing each of the rigid elements (34) and locatedon at least one surface of the linking element (3). These two chamfers(321) facilitate the bending of the linking element (3) in the directionof the surface on which they are located during movement of the patienton which the device (1) is implanted. Facilitating such bending (orfolding around the dampening element) of the linking element (3) may bedesired to increase the degree of freedom of the device (1) in at leastone direction. For example, in FIG. 4C, the chamfers (321) are presenton the ventral surface of the central portion (32), which facilitatesthe bending of the linking element in the direction of this ventralsurface and has the result of allowing the patient to lean forward moreeasily when the device (1) is implanted on the dorsal surface of thevertebrae. On the figures where these chamfers (321) are shown, they arelocated on only one surface, but the chamfers (321) could exist over thewhole periphery of the central portion if an increase in the degree offreedom of movement of the device in all directions is desired. Theangle of the chamfer can also be varied according to the degree offreedom wanted. Likewise, in other embodiments, the bending of thelinking element can be facilitated by including at least one slot (320)or cut-out on the central portion (32), close to its centre along thelongitudinal axis (L) located on at least one surface of the linkingelement (3), as shown for example in FIGS. 5A and 6A. This slot orcutout (320) can be disposed around all or part of the periphery of thecentral portion (32), and can extend through the whole thickness of thecentral portion (32), or through only a portion of the thickness of thecentral portion (32) if less facilitation of bending is desired.

The bending of the linking element (3) in at least one direction canalso be facilitated in some embodiments of the invention as shown inFIGS. 5B, 7A or 9, for example, by including on the rigid elements (34),at their end in contact with the central portion (32), a roundedexternal channel (341) that fits into a recess (322) of complementaryshape inside the central portion (32), as shown for example in FIG. 5C.This complementarity of shape facilitates the movements of the rigidelements (34) with respect to the central portion (32) during thebending of the linking element (3).

When the rigid elements (34) are hollow tubes, they may comprise aflared internal bore or channel (342) at the ends in contact with thecentral portion (32), as shown in FIG. 5B for example. FIG. 9 shows thedevice (1) during the bending of the linking element (3) in the courseof any movement of the patient and clearly shows the advantage obtainedwith the flared internal bore or channel (342) of the hollow tubes (34),as well as by the fit between the rounded external channel (341) and therecess (322) of complementary shape inside the central portion (32).These two channels (341, 342) and this complementarity of shapefacilitate the movement of the hollow tubes (34) in relation to thecentral portion (32).

Conversely, it is sometimes desirable to limit the bending of thelinking element (3) in at least one direction. The dampening element(31) can then, in different embodiments, include at least one bendingstop (310, 311) on at least one part of at least one of its surfaces.The bending stop (310, 311) will then oppose the bending of the linkingelement (3) in the direction of the surface on which this stop islocated. In addition, it is possible to include a first type (310) ofbending stop located on all the surfaces of the linking element (3)(i.e., all around the linking element (3)), which limits bending in alldirections, or another type (311) of bending stop located only on onesurface of the linking element (3), which limits bending along thatsurface. These bending stops (310, 311) can comprise an extension of thecentral portion (32) projecting from the rigid elements (34) or inseparate elements, fixed onto the central portion (32). In someembodiments, the bending stops (310, 311) can comprise an elasticmaterial that just partially opposes the bending of the linking element(3) or can comprise a rigid, inelastic material that totally opposes thebending of the linking element (3).

FIG. 7A depicts an embodiment of a device (1) to support threevertebrae. The device (1) in these types of embodiments includes threeimplants (2), each designed to be anchored to one of the vertebrae andconnected together by a linking element (3) that has three rigidelements (34) (hollow tubes shown in this embodiment as a non-limitativeexample) and two dampening elements (31) between the three rigidelements (34). In this embodiment, the central rigid element (34)located between the two dampening elements (31) differs from the otherrigid elements. For example, the central rigid element (34) in thisembodiment is longer and includes two ends designed to fit the dampeningelements (31). Another type of embodiment that can be used to supportthree successive adjacent vertebrae comprises a central implant (2)configured to fix two discrete linking elements (3). This embodimentwould include this double-fixing implant, two normal implants (2) andtwo linking elements (3) that each includes a dampening element (31).Collinear linking elements (3) could be fixed end-to-end in thedouble-fixing implant, and non-collinear linking elements (3) could befixed side-by-side in the double-fixing implant. FIG. 17 shows anon-limitative example of an embodiment of a double-fixing implant (2).In this example, the head of the implants comprises two recesses (orchannels or conduits) intended to the respective rigid elements (34) oflinking elements (3) substantially parallel to each other. Optionally,these linking elements may have different orientations by providingpolyaxial fixing means, such as, for example, a ball and socketconnection or a mobile base. FIGS. 18A and 18B show anothernon-limitative example of a possible embodiment of a double-fixingimplant (2), in which the head of the implant is adapted to receive twocollinear linking elements (3). Of course, the two linking elements (3)can also have an orientation different one of another since the head maycomprise polyaxial means for independently fixing each of the twocollinear linking elements (3).

FIG. 7B depicts another embodiment of a device (1) to support threevertebrae. In this embodiment, however, the device (1) allows thearthrodesis (total immobilization and intervertebral fusion) of a firstspace between a particular vertebrae, and flexible support for anotherspace between other vertebrae. In the illustrated embodiment, thelinking element (3) includes a first rigid element (34 a) (comprising,as a nonlimiting example, a hollow tube) connecting implants (2 a) and(2 b). The linking element (3) does not include a dampening elementbetween implants (2 a) and (2 b), to firmly fix the respective vertebraeand allow arthrodesis. A dampening element (31) is disposed betweenimplants (2 b) and (2 c), however, and connected to a second rigidelement (34 b) (also comprising, as a nonlimiting example, a hollowtube) fixed onto the third implant (2 c). This configuration, whichallows intervertebral fusion between the some vertebrae and providessupport for another intervertebral space, will be particularly usefulwhen the disc of the first intervertebral space is too damaged to bepreserved, and therefore requires an intervertebral fusion, while thedisc of the second space is damaged but can be preserved. In thisembodiment, the second disc is flexibly supported, potentiallypreventing or slowing its total collapse.

In the embodiments illustrated in FIGS. 7A and 7B, longitudinal elasticportion (33) extends throughout linking element (3). FIGS. 8A to 8E alsoshow embodiments of a vertebral support device for implantation on threevertebrae to allow the arthrodesis (complete intervertebralimmobilization and fusion) of a first intervertebral space whileflexibly supporting vertebrae on both sides of another intervertebralspace, but in these embodiments the longitudinal portion (33) extentsthrough only a portion of rigid element (34). The other portions of therigid element (34) may then be solid, as shown in FIGS. 8C and 8E, butmay well also be hollow, as long as the rigid element (34) comprises atleast one opening on at least one of its surfaces for fixing thelongitudinal portion (33) with respect to the rigid element (34). Theopening can receive a fastener (330, 331), as detailed hereafter. Forthe vertebral space to be fused, linking element (3) need not compriseany dampening element (31), and the longitudinal portion (33) canadequately extend only between the implants (2) anchored to thevertebrae to be flexibly supported by the device (1) while still havinga certain degree of freedom. Thus, in these embodiments, the linkingelement (3) comprises a first rigid element (34 a) which can be solid orhollow, between a first and a second implant, and a second rigid element(34 b) configured to accommodate longitudinal elastic element (33)(hollow, as a non-limiting example, in the illustrated embodiments). Adampening element (31) is disposed between first rigid element (34 a)and second rigid element (34 b). The extremity of first rigid element(34 a) proximal to the dampening element (31) can, as shown in FIGS. 8Cand 8E, be hollow and equipped with fasteners (330, 331) for thefixation of the longitudinal portion (33) inserted in this hollowextremity of the rigid element (34 a).

In the embodiment shown in FIGS. 8B and 8C, a fixing stop (331) providesthe fixation of the longitudinal portion (33) with respect to thishollow extremity of the rigid element (34 a). This stop (331) has adiameter larger than the diameter of the inner channel of the hollowportion of the first rigid element (34 a) and larger than the diameterof an opening (330 b) present on at least one of the surfaces (or onewall) of the rigid element (34 a). In the embodiment shown in FIGS. 8Dand 8E, removable lock (330) provides the fixation of the longitudinalportion (33) in the hollow portion of the first rigid element (34 a). Inthe illustrated embodiment, removable lock (33) comprises a stitching (awire or filament, for example) passing through a hole (330 b) (or boreor drilling) extend through the walls of the rigid element (34) and atleast one hole (330 a) in the longitudinal portion (33). Thus, theremovable lock comprises, in this example, a wire or filament (330)passing through the rigid element (34 a) and the longitudinal portion(33). The longitudinal portion (33) can comprise a plurality of holes(330 a) providing adjustment of its tension, as mentioned previously.Likewise, the other extremity of the longitudinal portion (33) cancomprise the same type of fastener as used in other embodimentsdescribed herein, such as, for example, a wire (330) passing through thehole(s) (330 a) extending through the longitudinal portion (33), asshown in FIG. 8A and suggested by FIGS. 8D and 8E. In another embodimentalready mentioned, the extremity of the longitudinal portion (33), whenit does not extend beyond the extremity of the rigid elements, can befixed with removable lock (330) passing through the hole(s) (330 a)extending through the longitudinal portion (33) and passing through thehole (or drilling) (330 b) extending through the rigid element (34).

FIGS. 10A, 10B and 10C, as well as FIGS. 11A, 11B and 11C show variousembodiments in which the rigid elements are solid bars, or at leastpartially solid, along some or all of their length. In theseembodiments, each of the solid bars (34) comprises along one of itssurfaces a groove, channel, or chute having a depth increasing from itscentral end, which cooperates with the central portion (32). In theembodiment of FIGS. 10(A to C), as particularly visible on FIG. 10C, atthe regions which attach to the implants (2), the rigid element (34)actually comprises a hollow tube. At this point, the groove, channel, orchute is transversely enclosed by a surface that provides a support forthe fixation of the rigid element. As in the previously presentedembodiments, this support surface can comprise a flat (340) intended tocooperate with the clamps (20) of the linking element (3) and theimplants (2). Thus, this surface forms a structure supporting the clamps(20), and the groove, channel, or chute proceeds through a hole allowingthe insertion of the longitudinal portion (33).

In the embodiment of FIGS. 11(A to C), as particularly visible in FIG.11C, the groove, channel, or chute is not enclosed and the rigid element(34) has a U-shape section along its entire length, the depth of thechute varying between the two extremities of the rigid element (34). Inthis embodiment, as visible on FIG. 11 B, the groove, channel, or chutehas at its ends a depth such that the longitudinal portion (33) can beinserted inside it without protruding from it. Thus, the lateral wallsof the groove, channel, or chute form a surface supporting the fixationof the rigid element (34) without crushing elastic longitudinal portion(33).

In the embodiments illustrated in FIGS. 10(A to C) and 11(A to C), thelongitudinal portion (33) is positioned along the rigid element (34) forpart of its length and inside the rigid element (34) for another part ofits length, thus leaving a surface for supporting the clamps (20) whichdo not crush the longitudinal portion (33). As described previously, thelongitudinal portion can be maintained in tension and fixed by thefasteners (330, 331) adapted to its structure, for example where thelongitudinal portion extends beyond the rigid elements. The supportsurface at the fixation end of the rigid elements (34) can be orientedtowards the clamps (20), as shown in FIGS. 10(A to C) or towards anotherinterior surface of the conduit inside the implants (2) as shown onFIGS. 11(A to C).

In some embodiments, the longitudinal portion (33) can comprise a kindof sheath (or sleeve) in which the rigid elements (34) are inserted, atleast partially. In these embodiments, the rigid elements can comprisesolid bars, which have less risk of damaging or impairing the centralportion (32) than do hollow tubes. The central (32) and longitudinal(33) portions can be realized in two separated elements, as shown inFIGS. 12A and 12B. In the illustrated embodiments, the longitudinalportion (33) covers both the central portion (32) and, at leastpartially, the rigid elements (34). The fixation of this longitudinalportion (33) on the rigid elements (34) by the fasteners (330, 331)ensures the cohesion of the ensemble. The central portion (32) can beattached to the rigid elements in various embodiments. In otherembodiments, the central (32) and longitudinal (33) portions can beunitary, as shown in FIGS. 12C and 12D. The rigid elements (34) and thecentral portion (32) can also be attached to each other or not.

FIGS. 12(A to D) show the fixation of the longitudinal portion (33) onthe bars (34), for example, by a removable fastener (330) comprising awire or filament passing through the bars (34) and the longitudinalportion (33), similarly to the embodiments described previously inreference to FIGS. 8D and 8E. Other embodiments can be adapted toreceive any other type of fastener (330, 331), removable or not.Preferably, the longitudinal portion is in tension at rest. In theseembodiments of FIGS. 12(A to D), the longitudinal portion is shorterthan the ensemble of the linking element (3), formed by the rigidelements (34) and the central portion (32), so that the fixation ends ofthe rigid elements (34) can receive the clamps (20) withoutinterference. FIGS. 12(A to D) thus show non-limitative examples offixation of the longitudinal portion (33) by removable fasteners (330)passing through the rigid elements (34) and the longitudinal portion(33). In other embodiments, the longitudinal portion (33) can be longerthat the ensemble of the linking element (3) and be kept stretched intension from both sides or extremities of this ensemble by fasteners(330, 331) such as, for example, staples or rings described previously.FIGS. 13A and 13B show a non-limitative example of such embodiment inwhich the longitudinal portion (33) is fastened by removable fasteners(330) fixed on each side of the ends of the linking element (3). In thisexample, the sheath formed by the longitudinal portion (33) is stretchedbeyond the two ends of the ensemble of the linking element (3) formed bythe central portion (32) and the rigid elements (34), the two ends ofthis sheath being compressed by removable fasteners (330) such as, forexample, the staples shown on FIGS. 13(A and B). Fasteners (330, 331)can then be fixed at the extremities of the longitudinal portion (33),and at either of the ends of the rigid elements (34) or on both sides ofthe rigid elements (34). This imposed tension of the longitudinalportion (33) by the fasteners (330, 331) can be established at thefactory or the surgical suite, for example by use of tension marksvisible on the periphery of the longitudinal portion (33), at theextremities where the fasteners (330, 331) are to be placed. In anotherembodiment, the longitudinal portion (33) can be stretched directly bythe clamps (20) of the implants (2). For example, in an embodiment inwhich the longitudinal portion (33) is a sheath threaded on the rigidelements (34), as described for example in reference to FIGS. 12(A to D)or 13(A and B), this sheath can be maintained in tension directly by theclamps (20) of the implants (2), to the extent that the longitudinalportion (33) is long enough (or can be stretched enough) to extend fromone implant (2) to the other. FIGS. 15A, 15B and 15C show anothernon-limitative example of possible embodiment in which the longitudinalportion is fixed, and thus stretched (maintained in extension) by theclamps (20) of the implants (2). In this example, the longitudinalportion (33) is inserted, as shown in FIGS. 15B and 15C, inside a hollowrigid element (34) comprising a longitudinal slit at least at one of itsend, as particularly visible on FIG. 15A. FIGS. 15B and 15C show thatthe clamps (20) of the implants, when tightened, compress the part ofthe rigid element (34) comprising the slit, which result in compressionof the longitudinal portion (33) and allows to keep it in tension.Staples or rings can be used as fasteners (330, 331), but otheralternatives described herein are possible, for example fixing stops atthe ends of the longitudinal portion cooperating with recesses on thebars. Alternatively, no dedicated fastener for the longitudinal portion(33) may be required in some embodiments, for example, where the clamps(20) are configured to fix longitudinal portion (33).

The different embodiments presented here are used to illustrate thepossible variants of this present invention, and show that the inventioncan be used in many different embodiments. Certain particularlyadvantageous embodiments of this present invention allow the tension ofthe longitudinal portion (33) to be adjusted during the assembly of thedevice (1). This assembly, of course, can occur in the factory or at theoperating table by the surgeon. In the factory, the tension can bemeasured precisely and, if necessary, be recorded on tension markersdisposed on at least one of the ends of the longitudinal portion (33),so that the surgeon is aware of the values of the tensions that he isadjusting. Accordingly, the present invention also concerns a processfor preparation of the device (1).

This process can be implemented in the factory before implantation, andthe device delivered assembled. Alternatively, this process can beimplemented by the surgeon who will receive the device (1) unassembled(at least in part) and who will assemble it with the tension that hewants. Any of the embodiments described herein that accommodateadjustment of the tension of the longitudinal portion (33) can beadapted for use in the process. The process includes the followingsteps:

-   -   placing the central portion (32) between the rigid elements        (34);    -   placing the longitudinal portion (33) in operative relation to        the rigid elements (34);    -   adjusting the tension of the longitudinal portion (33); and    -   fixing the longitudinal portion (33) in relation to the rigid        elements (34).

During the execution of this process, one implementation includesmarking at least one tension mark on the longitudinal portion (33) andadjusting the tension of the longitudinal portion (33). Anotherimplementation includes in the step of fixing the longitudinal portion(33) in relation to the rigid elements (34) includes a step of fasteningat least one end of the longitudinal portion (33) with one or morefasteners (330, 331). Another implementation includes inserting of atleast one removable lock (330) in at least one hole (330 a) in thelongitudinal portion (33), along an axis that is substantiallyperpendicular to the longitudinal axis (L). Such hole (330 a) canconstitutes a tension mark, and another implementation includes usingsuch a tension mark to determine the tension of the longitudinal portion(33), with another implementation including fixing disposing thefastener (330, 331) in a corresponding hole (or drilling) (330 b) in thewalls of the hollow tube (34). Such fixing by inserting a removable lock(330) inside at least one hole (330 a) present in the longitudinalportion (33), and in a hole (330 b) (or drilling) in the walls of thetube (34), optionally can be implemented by the insertion of a wire(330) through these holes and the tying of the wire, for example by thesurgeon during the implantation of the device (1).

In another implementation for devices (1) having rigid elements (34)that comprise solid bars equipped with a groove, channel, or chute,placement of the longitudinal portion (33) in operative relation to therigid elements (34) further comprises inserting the longitudinal portion(33) inside the groove, channel, or chute of the rigid elements (34). Asin the embodiment of FIGS. 10(A to C), this step of inserting thelongitudinal portion (33) inside the groove, channel, or chute can beassociated with a step of inserting the longitudinal portion (33) insidea hole extending the groove, channel, or chute at the fixation end ofthe rigid elements (34) at the level of the clamps (20) connecting theimplants and the linking element. In the embodiments where the rigidelements comprise hollow tubes, the step of placement of thelongitudinal portion (33) in operative relation to the rigid elements(34) further comprises a step of inserting the longitudinal portion (33)inside the conduit of the rigid elements (34) and inside a conduit ofthe central potion (32). In these implementations, placement of thelongitudinal portion (33) in operative relation to the rigid elements(34) can further comprise a step of fixing, at the end of thelongitudinal portion (33) opposite an end comprising a removablefasteners (330), a fixing stop (331) having an external diameter greaterto the diameter of the hollow tubes (34). In another implementation,placement of the longitudinal portion (33) in operative relation to therigid elements (34) further comprises inserting rigid elements (34)comprising solid bars and the central portion (32) inside a longitudinalportion (33) comprising an elastic sheath or sleeve.

Various steps of the various methods can be implemented before theimplantation of the device on the vertebrae. These steps may thenconstitute at least part of a method for assembling the device prior toimplantation. Alternatively, these steps constitute at least part ofvarious methods for implanting the device. During the implantation, thesurgeon implementing such a method can perform a step of adjustment ofthe position, along the longitudinal axis (L), of the rigid elements(34) with respect to the implants (2), followed by a step of blockingthe rigid elements (34) at the desired position by the clamps (20). Theimplantation of implants on the vertebrae and the adjustment of theorientation of a rigid element in relation to the axis of the spinalcolumn, using polyaxial implants, are described in detail in theapplications WO03/049629 and WO2005020829. The steps for implanting theimplants (2) by screwing the threaded portion (21) in the vertebralpedicles or by anchoring the hooks (21) into suitable shapes on thevertebrae or recesses made especially in the vertebrae thus do not haveto be detailed here. In many implantation procedures, it may bepreferable to anchor the implants (2) in the vertebrae without damagingthe articular processes (AP). Indeed, various embodiments of the presentdevice (1) are intended to relieve the intervertebral disc while leavingthe adjacent vertebrae with a freedom of movement rather than inducingan arthrodesis. Accordingly, in many procedures it may be preferable toleave the articular processes (AP) intact and to avoid their fusion.

Thus, during the implantation of bony anchorage implants (2) in thevertebrae (for example, in the vertebral pedicles), the surgeon may takemeasures to anchor the implants (2) in the vertebrae without damagingthe articular processes (AP).

In addition, the centering of the dampening element (31) with respect tothe vertebrae can be varied during the implantation. As particularlyvisible in the non-limitative examples of FIGS. 20 and 21, the implantsare anchored at the level of the pedicles of two adjacent vertebrae. Thedampening element (31) can then be centered with respect to thearticular processes (AP) between these two vertebrae, as particularlyvisible on FIG. 20, or can be centered with respect to theintervertebral space (IV), as particularly visible on FIG. 21. Thiscentering is performed by the surgeon when fixing the rigid elements(34) in operative relation to the implants (2), by adjusting theposition of the rigid elements (34) with respect to the implants (2),along the longitudinal axis (L). This step can also be associated with astep of selecting different rigid elements (34) having a length adaptedto the centering position chosen. During the implantation, the surgeoncan also adjust the spacing between the vertebrae, for example thanks toa known tool such as forceps. The device according the present inventionthen will allow this spacing to be maintained while leaving a freedom ofmovement to the patient.

When the surgeon has implanted the implants on the vertebrae, placed therigid elements with respect to the implants, and adjusted the tension ofthe longitudinal portion, the surgeon may elect to clamp only one of therigid elements (34) with respect to one of the implants (2), and then toadjust the spacing between the vertebrae before clamping the secondrigid element (34) with respect to the second implant (2). The method ofimplantation may thus comprise steps of fixing one of the rigid elements(34) with respect to one of the implants (2) with a clamp (20),centering the dampening element (31) with respect to the vertebrae,spreading the vertebrae apart (for example, using spreading forcepsknown in the field), and fixing the second rigid element (34) with aclamp (20) to maintain the desired spacing between the vertebrae. Theclamps (20), as mentioned previously, comprise tightening means which,in any of the embodiments in which the clamps (20) are on implants (2)comprising a longitudinal channel, allow the rigid elements (34) to beinserted and maintained in the head of the implants (2) without beingblocked initially, and then allow blocking them once their position isadjusted. The step of adjustment of the spacing between the vertebrae isfacilitated by the translation (along the longitudinal axis) of therigid elements with respect to the clamps and the tightening of thelatter.

As mentioned previously, embodiments using polyaxial anchors (2) canprovide adjustment of the orientation of the rigid elements (34).Associated methods can comprise a step of adjustment of the orientationof the longitudinal axis (L) of the rigid elements (34) with respect tothe axis of the spinal column, followed by a step of fixing the rigidelements (34) in the desired orientation. In some implementations,adjustment of the position of the rigid element and adjustment of itsorientation can be realized during the implantation of the device on thevertebrae. As mentioned previously, the step of adjusting theorientation can be followed by fixation at the chosen orientation, butthe orientation may be left free or restricted around a chosen position,even after the tightening of the clamps of the implants, and still bewithin the scope of the invention.

With the benefit of the disclosure above, those of skill in the art willrecognize that many of the various features of the differentillustrative embodiments presented here can be combined with each otherand with other features known in the art without departing from thescope or spirit of the present invention, and that the present inventioncan include embodiments in many other forms. Consequently, theembodiments described above must be considered illustrative only, andthe invention must not be limited to the details provided above.

1. A vertebral support device comprising: first and second osseousanchoring implants, each comprising a linking element fastener; and alinking element connecting the first and second osseous anchoringimplants, the linking element having a longitudinal axis and comprisingfirst and second rigid elements articulated by an elastic dampeningelement, the elastic dampening element comprising a compression stressabsorbing central elastic portion disposed at least partially betweenthe first and second rigid elements, and an extension stress absorbinglongitudinal elastic portion comprising first and second extremities,each fixed to the first or the second osseous anchoring implant or tothe first or the second rigid element.
 2. A vertebral support deviceaccording to claim 1, in which the linking element fasteners are clamps,and the first and second rigid elements are solid bars each having anend cooperating with one of the clamps and an end cooperating with thecentral elastic portion, the longitudinal elastic portion beingsubstantially parallel to the solid bars and having a lengthsubstantially greater than the aggregate lengths of the solid bars andthe central elastic portion
 3. A vertebral support device according toclaim 2, in which the longitudinal elastic portion is inserted at leastpartially in a groove, channel, or chute of each of the solid bars, andin which the clamps bear on the solid bars and not on the longitudinalelastic portion
 4. A vertebral support device according to claim 3, inwhich at least one of the grooves, channels, or chutes extends through ahole in an extremity of the respective solid bar, and the respectiveclamp bears on the surface of the solid bar closing said groove,channel, or chute
 5. A vertebral support device according to claim 4, inwhich the central elastic portion and the longitudinal elastic portioneach are comprised of a unitary weave or braid of synthetic fibershaving uniform elastic properties through the central elastic portionand the longitudinal elastic portion
 6. A vertebral support deviceaccording to claim 4, in which the central elastic portion and thelongitudinal elastic portion each are comprised of a unitary weave orbraid of synthetic fibers having different elastic properties throughthe central elastic portion and through the longitudinal elastic portion7. A vertebral support device according to claim 1, in which the centralelastic portion and the longitudinal elastic portion are discrete, thecentral elastic portion being hollow and having an inside dimensionalong the longitudinal elastic portion that is substantially the same asan outside dimension of the longitudinal elastic portion
 8. A vertebralsupport device according to claim 7, in which the first and second rigidelements are hollow tubes having an inside dimension substantiallylarger the inside dimension of the central elastic portion, and thelongitudinal elastic portion has an outside dimension along the firstand second rigid elements that is substantially the same as the insidedimension of the hollow tubes
 9. A vertebral support device according toclaim 7, in which the first and second rigid elements are hollow tubeshaving an inside dimension substantially the same as the insidedimension of the central elastic portion and outside dimension of thelongitudinal elastic portion
 10. A vertebral support device according toclaim 9, in which the each of the first and second rigid elements has aflared internal profile
 11. A vertebral support device according toclaim 1, in which the central elastic portion includes at least one slotor cut.
 12. A vertebral support device according to claim 1, in whichthe central elastic portion includes a chamfer facing an end of thefirst rigid element and a chamfer facing an end of the second rigidelement
 13. A vertebral support device according to claim 1, in whichthe dampening element comprises a bending stop.
 14. A vertebral supportdevice according to claim 13, in which the bending stop comprises arigid, inelastic material totally opposing the bending of the linkingelement
 15. A vertebral support device according to claim 1, in which atleast one of the extremities of the longitudinal elastic portion isadjustably fixed to the first or the second osseous anchoring implant orto the first or the second rigid element with a dampening elementfastener, and in which the longitudinal elastic portion has a tensionadjustable at least in part by the dampening element fastener.
 16. Avertebral support device according to claim 15, in which thelongitudinal elastic portion comprises a hole setting a tension mark andthe dampening element fastener comprises a removable lock fitting thehole and determining the tension of the longitudinal elastic portion.